Michael I. Collector

Multi-Organ, Multi-Lineage Engraftment by a Single Bone Marrow-Derived Stem Cell

Purification of rare hematopoietic stem cell(s) (HSC) to homogeneity is required to study their self-renewal, differentiation, phenotype, and homing. Long-term repopulation (LTR) of irradiated hosts and serial transplantation to secondary hosts represent the gold standard for demonstrating self-renewal and differentiation, the defining properties of HSC. We show that rare cells that home to bone marrow can LTR primary and secondary recipients. During the homing, CD34 and SCA-1 expression increases uniquely on cells that home to marrow. These adult bone marrow cells have tremendous differentiative capacity as they can also differentiate into epithelial cells of the liver, lung, GI tract, and skin. This finding may contribute to clinical treatment of genetic disease or tissue repair.

A clinically relevant population of leukemic CD34+CD38- cells in acute myeloid leukemia

Relapse of acute myeloid leukemia (AML) is thought to reflect the failure of current therapies to adequately target leukemia stem cells (LSCs), the rare, resistant cells presumed responsible for maintenance of the leukemia and typically enriched in the CD34(+)CD38(-) cell population. Despite the considerable research on LSCs over the past 2 decades, the clinical significance of these cells remains uncertain. However, if clinically relevant, it is expected that LSCs would be enriched in minimal residual disease and predictive of relapse. CD34(+) subpopulations from AML patients were analyzed by flow cytometry throughout treatment. Sorted cell populations were analyzed by fluorescence in situ hybridization for leukemia-specific cytogenetic abnormalities (when present) and by transplantation into immunodeficient mice to determine self-renewal capacity. Intermediate (int) levels of aldehyde dehydrogenase (ALDH) activity reliably distinguished leukemic CD34(+)CD38(-) cells capable of engrafting immunodeficient mice from residual normal hematopoietic stem cells that exhibited relatively higher ALDH activity. Minimal residual disease detected during complete remission was enriched for the CD34(+)CD38(-)ALDH(int) leukemic cells, and the presence of these cells after therapy highly correlated with subsequent clinical relapse. ALDH activity appears to distinguish normal from leukemic CD34(+)CD38(-) cells and identifies those AML cells associated with relapse.

Homing of Long-Term and Short-Term Engrafting Cells In Vivoa

Abstract: Long‐term repopulating hematopoietic stem cells can be separated from cells which provided radioprotection (short‐term repopulating cells) on the basis of size. This might be a result of the quiescent nature of long‐term repopulating cells. To define the activity of these populations we utilized a dye, PKH26+, which incorporates into the membrane of cells and is equally distributed to daughter cells when they divide. We were able to retrieve PKH26+‐labeled cells posttransplant in the hematopoietic tissues of the recipients. We could also assess their cell cycle status and their ability, short‐and long‐term, to reconstitute secondary lethally irradiated hosts in limiting dilution. The results suggest that long‐term repopulating cells remain quiescent in the bone marrow shortly after engraftment, whereas cells which radioprotect are more rapidly dividing. We could not detect labeled cells in the peripheral blood posttransplant, and even though cells homed to both the spleen and bone marrow the cells in the bone marrow were significantly more competent at reconstituting lethally irradiated secondary hosts.

Hematopoietic Progenitor Stem Cell Homing in Mice Lethally Irradiated with Ionizing Radiation at Differing Dose Rates

Abstract Collis, S. J., Neutzel, S., Thompson, T. L., Swartz, M. J., Dillehay, L. E., Collector, M. I., Sharkis, S. J. and DeWeese, T. L. Hematopoietic Progenitor Stem Cell Homing in Mice Lethally Irradiated with Ionizing Radiation at Differing Dose Rates. Radiat. Res. 162, 48–55 (2004). It has recently been shown that specific lineage-depleted murine hematopoietic stem cells that home to the bone marrow 2 days after transplantation of ablated primary recipients are capable of long-term engraftment and repopulation of secondary recipients. We were interested in determining whether the rate at which the ablating radiation dose was delivered to the mice affected the homing of lineage-depleted stem cells to the bone marrow and/or sites of tissue damage. Fractionated, lineage-depleted donor marrow cells were isolated and labeled with the membrane dye PKH26. Recipient mice were lethally irradiated with 11 Gy ionizing radiation using varying dose rates and were immediately injected with PKH26-labeled progenitor stem cells. With the exception of the lowest dose-rate group, all irradiated mice had an approximately fivefold (P = 0.014 to 0.025) reduction in stem cell homing to the bone marrow compared to unirradiated control animals. A fivefold reduction of stem cell homing to the spleen compared to unirradiated animals was also observed, though this was not statistically significant for any dose-rate group (P = 0.072 to 0.233). This difference in homing could not be explained by increased stem cell apoptosis/necrosis or non-marrow tissue homing to the intestine, lung or liver. We show that the dose rate at which a lethal dose of total-body radiation is delivered does not augment hematopoietic progenitor stem cell homing to the bone marrow, spleen or sites of early radiation-mediated tissue damage at either 2 or 5 days postirradiation/transplantation. The observation that greater homing was seen in unirradiated control mice calls into question the concept that adequate bone marrow stem cell homing requires radiation-induced “space” to be made in the marrow, certainly for the enriched early progenitor hematopoietic stem cells used for this set of experiments. Further experiments will be needed to determine whether these homed cells are as capable of giving rise to long-term engraftment/repopulation of the marrow of secondary recipients as they are in irradiated recipients.

Using divisional history to measure hematopoietic stem cell self-renewal and differentiation

OBJECTIVES The purpose of this study was to investigate cell fates and long-term repopulating potential of a primitive hematopoietic stem cell (HSC) population (i.e., FR25Lin(-) cells) in vitro. MATERIALS AND METHODS FR25Lin(-) cells were isolated by elutriation and cell sorting and cultured with a combination of cytokines for 7 days. Utilizing the membrane dye PKH-26, cultured cells were separated into two subsets based on their proliferation rates and assayed for progenitors and HSC. RESULTS Fresh FR25Lin(-) cells were mostly quiescent; however, some of this population entered cell cycle after cytokine exposure reaching a peak 4 to 5 days after culture. Two subsets of cultured cells were isolated: 1) cells that had divided several times (PKH(dull) cells) and 2) cells that remained undivided or divided only once or twice (PKH(bright) cells). The PKH(dull) cells accounted for 94% of total viable cells in culture after 5 days. The PKH(dull) subset contained all the multi-potential in vivo progenitors (CFU-S) and 10 times more committed progenitors (CFU-C). Quantitative analysis of HSC engraftment from the PKH(bright) subset demonstrated stem cell maintenance. For the PKH(dull) subset, on day 5, HSC numbers increased. By day 7, increased differentiation in the PKH(dull) population supports expanding differentiation divisions. CONCLUSIONS Our primitive HSC population underwent different types of cell divisions stimulated by cytokines, resulting in subsets with different self-renewal and differentiation potentials. This in vitro/in vivo model provides a useful tool for studies of early events during HSC self-renewal and differentiation.

Phenotype and Function of Hematopoietic Stem Cells

Abstract: Using an in vivo selection technique, we can isolate individual cells that can repopulate the hematopoietic system of a lethally irradiated murine recipient. These cells rapidly acquire a CD34 phenotype in the animal. Progenitors in our long‐term chimeras are of donor type. We also have evidence that transplantation of limiting numbers (as low as a single cell) that have this long‐term repopulating ability (LTRA) can self‐renew. This is demonstrated by serial transplantation of marrow from engrafted recipients 11 months post transplant into new hosts for four additional months.